section ‹Old Datatype package: constructing datatypes from Cartesian Products and Disjoint Sums›
theory Old_Datatype
imports Main
begin
subsection ‹The datatype universe›
definition "Node = {p. ∃f x k. p = (f :: nat => 'b + nat, x ::'a + nat) ∧ f k = Inr 0}"
typedef ('a, 'b) node = "Node :: ((nat => 'b + nat) * ('a + nat)) set"
morphisms Rep_Node Abs_Node
unfolding Node_def by auto
text‹Datatypes will be represented by sets of type ‹node››
type_synonym 'a item = "('a, unit) node set"
type_synonym ('a, 'b) dtree = "('a, 'b) node set"
definition Push :: "[('b + nat), nat => ('b + nat)] => (nat => ('b + nat))"
where "Push == (%b h. case_nat b h)"
definition Push_Node :: "[('b + nat), ('a, 'b) node] => ('a, 'b) node"
where "Push_Node == (%n x. Abs_Node (apfst (Push n) (Rep_Node x)))"
definition Atom :: "('a + nat) => ('a, 'b) dtree"
where "Atom == (%x. {Abs_Node((%k. Inr 0, x))})"
definition Scons :: "[('a, 'b) dtree, ('a, 'b) dtree] => ('a, 'b) dtree"
where "Scons M N == (Push_Node (Inr 1) ` M) Un (Push_Node (Inr (Suc 1)) ` N)"
definition Leaf :: "'a => ('a, 'b) dtree"
where "Leaf == Atom ∘ Inl"
definition Numb :: "nat => ('a, 'b) dtree"
where "Numb == Atom ∘ Inr"
definition In0 :: "('a, 'b) dtree => ('a, 'b) dtree"
where "In0(M) == Scons (Numb 0) M"
definition In1 :: "('a, 'b) dtree => ('a, 'b) dtree"
where "In1(M) == Scons (Numb 1) M"
definition Lim :: "('b => ('a, 'b) dtree) => ('a, 'b) dtree"
where "Lim f == ⋃{z. ∃x. z = Push_Node (Inl x) ` (f x)}"
definition ndepth :: "('a, 'b) node => nat"
where "ndepth(n) == (%(f,x). LEAST k. f k = Inr 0) (Rep_Node n)"
definition ntrunc :: "[nat, ('a, 'b) dtree] => ('a, 'b) dtree"
where "ntrunc k N == {n. n∈N ∧ ndepth(n)<k}"
definition uprod :: "[('a, 'b) dtree set, ('a, 'b) dtree set]=> ('a, 'b) dtree set"
where "uprod A B == UN x:A. UN y:B. { Scons x y }"
definition usum :: "[('a, 'b) dtree set, ('a, 'b) dtree set]=> ('a, 'b) dtree set"
where "usum A B == In0`A Un In1`B"
definition Split :: "[[('a, 'b) dtree, ('a, 'b) dtree]=>'c, ('a, 'b) dtree] => 'c"
where "Split c M == THE u. ∃x y. M = Scons x y ∧ u = c x y"
definition Case :: "[[('a, 'b) dtree]=>'c, [('a, 'b) dtree]=>'c, ('a, 'b) dtree] => 'c"
where "Case c d M == THE u. (∃x . M = In0(x) ∧ u = c(x)) ∨ (∃y . M = In1(y) ∧ u = d(y))"
definition dprod :: "[(('a, 'b) dtree * ('a, 'b) dtree)set, (('a, 'b) dtree * ('a, 'b) dtree)set]
=> (('a, 'b) dtree * ('a, 'b) dtree)set"
where "dprod r s == UN (x,x'):r. UN (y,y'):s. {(Scons x y, Scons x' y')}"
definition dsum :: "[(('a, 'b) dtree * ('a, 'b) dtree)set, (('a, 'b) dtree * ('a, 'b) dtree)set]
=> (('a, 'b) dtree * ('a, 'b) dtree)set"
where "dsum r s == (UN (x,x'):r. {(In0(x),In0(x'))}) Un (UN (y,y'):s. {(In1(y),In1(y'))})"
lemma apfst_convE:
"[| q = apfst f p; !!x y. [| p = (x,y); q = (f(x),y) |] ==> R
|] ==> R"
by (force simp add: apfst_def)
lemma Push_inject1: "Push i f = Push j g ==> i=j"
apply (simp add: Push_def fun_eq_iff)
apply (drule_tac x=0 in spec, simp)
done
lemma Push_inject2: "Push i f = Push j g ==> f=g"
apply (auto simp add: Push_def fun_eq_iff)
apply (drule_tac x="Suc x" in spec, simp)
done
lemma Push_inject:
"[| Push i f =Push j g; [| i=j; f=g |] ==> P |] ==> P"
by (blast dest: Push_inject1 Push_inject2)
lemma Push_neq_K0: "Push (Inr (Suc k)) f = (%z. Inr 0) ==> P"
by (auto simp add: Push_def fun_eq_iff split: nat.split_asm)
lemmas Abs_Node_inj = Abs_Node_inject [THEN [2] rev_iffD1]
lemma Node_K0_I: "(λk. Inr 0, a) ∈ Node"
by (simp add: Node_def)
lemma Node_Push_I: "p ∈ Node ⟹ apfst (Push i) p ∈ Node"
apply (simp add: Node_def Push_def)
apply (fast intro!: apfst_conv nat.case(2)[THEN trans])
done
subsection‹Freeness: Distinctness of Constructors›
lemma Scons_not_Atom [iff]: "Scons M N ≠ Atom(a)"
unfolding Atom_def Scons_def Push_Node_def One_nat_def
by (blast intro: Node_K0_I Rep_Node [THEN Node_Push_I]
dest!: Abs_Node_inj
elim!: apfst_convE sym [THEN Push_neq_K0])
lemmas Atom_not_Scons [iff] = Scons_not_Atom [THEN not_sym]
lemma inj_Atom: "inj(Atom)"
apply (simp add: Atom_def)
apply (blast intro!: inj_onI Node_K0_I dest!: Abs_Node_inj)
done
lemmas Atom_inject = inj_Atom [THEN injD]
lemma Atom_Atom_eq [iff]: "(Atom(a)=Atom(b)) = (a=b)"
by (blast dest!: Atom_inject)
lemma inj_Leaf: "inj(Leaf)"
apply (simp add: Leaf_def o_def)
apply (rule inj_onI)
apply (erule Atom_inject [THEN Inl_inject])
done
lemmas Leaf_inject [dest!] = inj_Leaf [THEN injD]
lemma inj_Numb: "inj(Numb)"
apply (simp add: Numb_def o_def)
apply (rule inj_onI)
apply (erule Atom_inject [THEN Inr_inject])
done
lemmas Numb_inject [dest!] = inj_Numb [THEN injD]
lemma Push_Node_inject:
"[| Push_Node i m =Push_Node j n; [| i=j; m=n |] ==> P
|] ==> P"
apply (simp add: Push_Node_def)
apply (erule Abs_Node_inj [THEN apfst_convE])
apply (rule Rep_Node [THEN Node_Push_I])+
apply (erule sym [THEN apfst_convE])
apply (blast intro: Rep_Node_inject [THEN iffD1] trans sym elim!: Push_inject)
done
lemma Scons_inject_lemma1: "Scons M N <= Scons M' N' ==> M<=M'"
unfolding Scons_def One_nat_def
by (blast dest!: Push_Node_inject)
lemma Scons_inject_lemma2: "Scons M N <= Scons M' N' ==> N<=N'"
unfolding Scons_def One_nat_def
by (blast dest!: Push_Node_inject)
lemma Scons_inject1: "Scons M N = Scons M' N' ==> M=M'"
apply (erule equalityE)
apply (iprover intro: equalityI Scons_inject_lemma1)
done
lemma Scons_inject2: "Scons M N = Scons M' N' ==> N=N'"
apply (erule equalityE)
apply (iprover intro: equalityI Scons_inject_lemma2)
done
lemma Scons_inject:
"[| Scons M N = Scons M' N'; [| M=M'; N=N' |] ==> P |] ==> P"
by (iprover dest: Scons_inject1 Scons_inject2)
lemma Scons_Scons_eq [iff]: "(Scons M N = Scons M' N') = (M=M' ∧ N=N')"
by (blast elim!: Scons_inject)
lemma Scons_not_Leaf [iff]: "Scons M N ≠ Leaf(a)"
unfolding Leaf_def o_def by (rule Scons_not_Atom)
lemmas Leaf_not_Scons [iff] = Scons_not_Leaf [THEN not_sym]
lemma Scons_not_Numb [iff]: "Scons M N ≠ Numb(k)"
unfolding Numb_def o_def by (rule Scons_not_Atom)
lemmas Numb_not_Scons [iff] = Scons_not_Numb [THEN not_sym]
lemma Leaf_not_Numb [iff]: "Leaf(a) ≠ Numb(k)"
by (simp add: Leaf_def Numb_def)
lemmas Numb_not_Leaf [iff] = Leaf_not_Numb [THEN not_sym]
lemma ndepth_K0: "ndepth (Abs_Node(%k. Inr 0, x)) = 0"
by (simp add: ndepth_def Node_K0_I [THEN Abs_Node_inverse] Least_equality)
lemma ndepth_Push_Node_aux:
"case_nat (Inr (Suc i)) f k = Inr 0 ⟶ Suc(LEAST x. f x = Inr 0) ≤ k"
apply (induct_tac "k", auto)
apply (erule Least_le)
done
lemma ndepth_Push_Node:
"ndepth (Push_Node (Inr (Suc i)) n) = Suc(ndepth(n))"
apply (insert Rep_Node [of n, unfolded Node_def])
apply (auto simp add: ndepth_def Push_Node_def
Rep_Node [THEN Node_Push_I, THEN Abs_Node_inverse])
apply (rule Least_equality)
apply (auto simp add: Push_def ndepth_Push_Node_aux)
apply (erule LeastI)
done
lemma ntrunc_0 [simp]: "ntrunc 0 M = {}"
by (simp add: ntrunc_def)
lemma ntrunc_Atom [simp]: "ntrunc (Suc k) (Atom a) = Atom(a)"
by (auto simp add: Atom_def ntrunc_def ndepth_K0)
lemma ntrunc_Leaf [simp]: "ntrunc (Suc k) (Leaf a) = Leaf(a)"
unfolding Leaf_def o_def by (rule ntrunc_Atom)
lemma ntrunc_Numb [simp]: "ntrunc (Suc k) (Numb i) = Numb(i)"
unfolding Numb_def o_def by (rule ntrunc_Atom)
lemma ntrunc_Scons [simp]:
"ntrunc (Suc k) (Scons M N) = Scons (ntrunc k M) (ntrunc k N)"
unfolding Scons_def ntrunc_def One_nat_def
by (auto simp add: ndepth_Push_Node)
lemma ntrunc_one_In0 [simp]: "ntrunc (Suc 0) (In0 M) = {}"
apply (simp add: In0_def)
apply (simp add: Scons_def)
done
lemma ntrunc_In0 [simp]: "ntrunc (Suc(Suc k)) (In0 M) = In0 (ntrunc (Suc k) M)"
by (simp add: In0_def)
lemma ntrunc_one_In1 [simp]: "ntrunc (Suc 0) (In1 M) = {}"
apply (simp add: In1_def)
apply (simp add: Scons_def)
done
lemma ntrunc_In1 [simp]: "ntrunc (Suc(Suc k)) (In1 M) = In1 (ntrunc (Suc k) M)"
by (simp add: In1_def)
subsection‹Set Constructions›
lemma uprodI [intro!]: "⟦M∈A; N∈B⟧ ⟹ Scons M N ∈ uprod A B"
by (simp add: uprod_def)
lemma uprodE [elim!]:
"⟦c ∈ uprod A B;
⋀x y. ⟦x ∈ A; y ∈ B; c = Scons x y⟧ ⟹ P
⟧ ⟹ P"
by (auto simp add: uprod_def)
lemma uprodE2: "⟦Scons M N ∈ uprod A B; ⟦M ∈ A; N ∈ B⟧ ⟹ P⟧ ⟹ P"
by (auto simp add: uprod_def)
lemma usum_In0I [intro]: "M ∈ A ⟹ In0(M) ∈ usum A B"
by (simp add: usum_def)
lemma usum_In1I [intro]: "N ∈ B ⟹ In1(N) ∈ usum A B"
by (simp add: usum_def)
lemma usumE [elim!]:
"⟦u ∈ usum A B;
⋀x. ⟦x ∈ A; u=In0(x)⟧ ⟹ P;
⋀y. ⟦y ∈ B; u=In1(y)⟧ ⟹ P
⟧ ⟹ P"
by (auto simp add: usum_def)
lemma In0_not_In1 [iff]: "In0(M) ≠ In1(N)"
unfolding In0_def In1_def One_nat_def by auto
lemmas In1_not_In0 [iff] = In0_not_In1 [THEN not_sym]
lemma In0_inject: "In0(M) = In0(N) ==> M=N"
by (simp add: In0_def)
lemma In1_inject: "In1(M) = In1(N) ==> M=N"
by (simp add: In1_def)
lemma In0_eq [iff]: "(In0 M = In0 N) = (M=N)"
by (blast dest!: In0_inject)
lemma In1_eq [iff]: "(In1 M = In1 N) = (M=N)"
by (blast dest!: In1_inject)
lemma inj_In0: "inj In0"
by (blast intro!: inj_onI)
lemma inj_In1: "inj In1"
by (blast intro!: inj_onI)
lemma Lim_inject: "Lim f = Lim g ==> f = g"
apply (simp add: Lim_def)
apply (rule ext)
apply (blast elim!: Push_Node_inject)
done
lemma ntrunc_subsetI: "ntrunc k M <= M"
by (auto simp add: ntrunc_def)
lemma ntrunc_subsetD: "(!!k. ntrunc k M <= N) ==> M<=N"
by (auto simp add: ntrunc_def)
lemma ntrunc_equality: "(!!k. ntrunc k M = ntrunc k N) ==> M=N"
apply (rule equalityI)
apply (rule_tac [!] ntrunc_subsetD)
apply (rule_tac [!] ntrunc_subsetI [THEN [2] subset_trans], auto)
done
lemma ntrunc_o_equality:
"[| !!k. (ntrunc(k) ∘ h1) = (ntrunc(k) ∘ h2) |] ==> h1=h2"
apply (rule ntrunc_equality [THEN ext])
apply (simp add: fun_eq_iff)
done
lemma uprod_mono: "[| A<=A'; B<=B' |] ==> uprod A B <= uprod A' B'"
by (simp add: uprod_def, blast)
lemma usum_mono: "[| A<=A'; B<=B' |] ==> usum A B <= usum A' B'"
by (simp add: usum_def, blast)
lemma Scons_mono: "[| M<=M'; N<=N' |] ==> Scons M N <= Scons M' N'"
by (simp add: Scons_def, blast)
lemma In0_mono: "M<=N ==> In0(M) <= In0(N)"
by (simp add: In0_def Scons_mono)
lemma In1_mono: "M<=N ==> In1(M) <= In1(N)"
by (simp add: In1_def Scons_mono)
lemma Split [simp]: "Split c (Scons M N) = c M N"
by (simp add: Split_def)
lemma Case_In0 [simp]: "Case c d (In0 M) = c(M)"
by (simp add: Case_def)
lemma Case_In1 [simp]: "Case c d (In1 N) = d(N)"
by (simp add: Case_def)
lemma ntrunc_UN1: "ntrunc k (UN x. f(x)) = (UN x. ntrunc k (f x))"
by (simp add: ntrunc_def, blast)
lemma Scons_UN1_x: "Scons (UN x. f x) M = (UN x. Scons (f x) M)"
by (simp add: Scons_def, blast)
lemma Scons_UN1_y: "Scons M (UN x. f x) = (UN x. Scons M (f x))"
by (simp add: Scons_def, blast)
lemma In0_UN1: "In0(UN x. f(x)) = (UN x. In0(f(x)))"
by (simp add: In0_def Scons_UN1_y)
lemma In1_UN1: "In1(UN x. f(x)) = (UN x. In1(f(x)))"
by (simp add: In1_def Scons_UN1_y)
lemma dprodI [intro!]:
"⟦(M,M') ∈ r; (N,N') ∈ s⟧ ⟹ (Scons M N, Scons M' N') ∈ dprod r s"
by (auto simp add: dprod_def)
lemma dprodE [elim!]:
"⟦c ∈ dprod r s;
⋀x y x' y'. ⟦(x,x') ∈ r; (y,y') ∈ s;
c = (Scons x y, Scons x' y')⟧ ⟹ P
⟧ ⟹ P"
by (auto simp add: dprod_def)
lemma dsum_In0I [intro]: "(M,M') ∈ r ⟹ (In0(M), In0(M')) ∈ dsum r s"
by (auto simp add: dsum_def)
lemma dsum_In1I [intro]: "(N,N') ∈ s ⟹ (In1(N), In1(N')) ∈ dsum r s"
by (auto simp add: dsum_def)
lemma dsumE [elim!]:
"⟦w ∈ dsum r s;
⋀x x'. ⟦ (x,x') ∈ r; w = (In0(x), In0(x')) ⟧ ⟹ P;
⋀y y'. ⟦ (y,y') ∈ s; w = (In1(y), In1(y')) ⟧ ⟹ P
⟧ ⟹ P"
by (auto simp add: dsum_def)
lemma dprod_mono: "[| r<=r'; s<=s' |] ==> dprod r s <= dprod r' s'"
by blast
lemma dsum_mono: "[| r<=r'; s<=s' |] ==> dsum r s <= dsum r' s'"
by blast
lemma dprod_Sigma: "(dprod (A × B) (C × D)) <= (uprod A C) × (uprod B D)"
by blast
lemmas dprod_subset_Sigma = subset_trans [OF dprod_mono dprod_Sigma]
lemma dprod_subset_Sigma2:
"(dprod (Sigma A B) (Sigma C D)) <= Sigma (uprod A C) (Split (%x y. uprod (B x) (D y)))"
by auto
lemma dsum_Sigma: "(dsum (A × B) (C × D)) <= (usum A C) × (usum B D)"
by blast
lemmas dsum_subset_Sigma = subset_trans [OF dsum_mono dsum_Sigma]
lemma Domain_dprod [simp]: "Domain (dprod r s) = uprod (Domain r) (Domain s)"
by auto
lemma Domain_dsum [simp]: "Domain (dsum r s) = usum (Domain r) (Domain s)"
by auto
text ‹hides popular names›
hide_type (open) node item
hide_const (open) Push Node Atom Leaf Numb Lim Split Case
ML_file ‹~~/src/HOL/Tools/Old_Datatype/old_datatype.ML›
end